A display driving system includes a timing controller configured to receive a data signal composed of image data and generate a control signal such as a clock signal; an interface configured to transmit the data signal and the control signal to a plurality of data drivers; the data drivers configured to receive the data signal and the control signal through the interface and supply received signals to a display panel to display an image; and a monitoring unit configured to feed back lock signals indicative of state information of the data drivers to the timing controller such that the data drivers can be monitored.
|
1. A display driving system comprising:
a timing controller configured to receive a data signal composed of image data and generate a control signal such as a clock signal;
an interface configured to transmit the data signal and the control signal to a plurality of data drivers;
the data drivers configured to receive the data signal and the control signal through the interface and supply received signals to a display panel to display an image; and
a monitoring unit configured to feed back one or more lock signals indicative of state information of one or more of the data drivers to the timing controller such that the data drivers can be monitored,
wherein when a first data driver from the plurality of data drivers is in an abnormal state due to electromagnetic interference (EMI) or noise, the first data driver outputs a first lock signal indicating that the first data driver is in the abnormal state.
2. The display driving system according to
wherein the monitoring unit comprises a sequential transmission section which sequentially connects the data drivers with one another such that the data drivers can sequentially transmit the lock signals indicating their respective state information to other adjoining data drivers, and which connects a finally positioned data driver to the timing controller such that the finally positioned data driver can feed back a lock signal to the timing controller.
3. The display driving system according to
wherein the monitoring unit comprises first through Nth sequential transmission sections which are configured to divide the plurality of data drivers into N (N is a natural number identical to or greater than 1) number of groups each of which is composed of one or more data drivers, and connect the data drivers of the respective groups with one another in such a way as to sequentially transmit the lock signals to adjoining data drivers, such that last data drivers of the respective groups which receive the lock signals are connected to the timing controller so that the lock signals of the respective groups can be transmitted and fed back to the timing controller.
4. The display driving system according to
5. The display driving system according to
6. The display driving system according to
wherein the monitoring unit comprises a lock signal output section which independently transmits the lock signals outputted from the plurality of data drivers to a logic gate, and the logic gate which is connected to the timing controller, combines one or more lock signals outputted from the lock signal output section, executes a logical operation and outputs a resultant signal to the timing controller.
7. The display driving system according to
wherein, if the first lock signal is outputted from the first data driver, the first data driver neglects the data signal transmitted through the interface and drives the display panel using previously inputted data; and
wherein the timing controller is configured to transmit a preamble signal as deskewing data between the data signal and the clock signal or a clock training signal for recovery of the clock signal, to the first data driver until a second lock signal indicating that the first data driver is in a normal state is fed back.
8. The display driving system according to
wherein the monitoring unit comprises first through Mth lock signal output sections which are configured to divide the plurality of data drivers into M (M is a natural number identical to or greater than 1) number of groups each of which is composed of one or more data drivers, and transmit independently the lock signals outputted from the data drivers constituting the respective groups to logic gates, and first through Mth logic gates which are configured to receive the lock signals transmitted from the respective groups of the first through Mth lock signal output sections, execute logical operations, and feed back output values thereof to the timing controller.
9. The display driving system according to
wherein, if the first lock signal is outputted from the first data driver, the first data driver neglects the data signal transmitted through the interface and drives the display panel using previously inputted data; and
wherein the timing controller is configured to transmit a preamble signal as deskewing data between the data signal and the clock signal or a clock training signal for recovery of the clock signal, to the first data driver until a second lock signal indicating that the first data driver is in a normal state is fed back.
10. The display driving system according to
11. The display driving system according to
wherein, if the first lock signal is outputted from the first data driver, the first data driver neglects the data signal transmitted through the interface and drives the display panel using previously inputted data; and
wherein the timing controller is configured to transmit a preamble signal as deskewing data between the data signal and the clock signal or a clock training signal for recovery of the clock signal, to the first data driver until a second lock signal indicating that the first data driver is in a normal state is fed back.
12. The display driving system according to
13. The display driving system according to
14. The display driving system according to
|
The present invention relates to a display driving system, and more particularly, to a display driving system with a unit for monitoring data drivers, which can monitor changes in the states of data drivers while a timing controller processes a clock signal and a data signal transmitted through an interface and supplies processed signals to a display panel, such that the state information of the data drivers can be fed back to the timing controller.
In general, a display driving system includes a timing controller configured to process a data signal and generate and supply a clock signal and a timing control signal so as to drive a display panel, and data drivers (data driver ICs) configured to drive the display panel using the image data and the timing control signal transmitted from the timing controller.
Interfaces for transmitting the image data to be displayed between the timing controller and the data drivers include a multi-drop transmission type interface in which the data drivers share a data signal line and a clock signal line, a PPDS (point-to-point differential signaling) transmission type interface in which data signals are separately supplied to the respective data drivers and a clock signal is shared by the data drivers, and an interface in which a data signal and a clock signal are distinguished by multiple levels and a data differential signal embedded with the clock signal is transmitted to the data drivers through respective independent signal lines.
However, in the conventional display driving system, the timing controller consistently transmits the data signal and the control signal to the data drivers irrespective of the states of the data drivers.
Therefore, even when the data drivers are placed in abnormal states due to electromagnetic interference (EMI) caused during high speed data transmission or noise, since the timing controller consistently transmits the data signal and the control signal to the data drivers cannot properly recognize the states of the data drivers, a problem is caused in that appropriate measures cannot be taken.
Accordingly, the present invention has been made in an effort to solve the problems occurring in the related art, and an object of the present invention is to provide a display driving system with a unit for monitoring data drivers, which has a unit capable of feeding back a control signal indicative of states of data drivers to a timing controller such that the timing controller having recognized the states of the data drivers can transmit a data signal and a control signal appropriate for normalizing a data driver operating in an abnormal state so that the data driver can be quickly recovered to a normal operation.
In order to achieve the above object, according to one aspect of the present invention, there is provided a display driving system comprising a timing controller configured to receive a data signal composed of image data and generate a control signal such as a clock signal; an interface configured to transmit the data signal and the control signal to a plurality of data drivers; the data drivers configured to receive the data signal and the control signal through the interface and supply received signals to a display panel to display an image; and a monitoring unit configured to feed back LOCK signals indicative of state information of the data drivers to the timing controller such that the data drivers can be monitored.
The above objects, and other features and advantages of the present invention will become more apparent after a reading of the following detailed description taken in conjunction with the drawings, in which:
Reference will now be made in greater detail to preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numerals will be used throughout the drawings and the description to refer to the same or like parts.
A display driving system with a unit for monitoring data drivers according to the present invention includes a timing controller 100 configured to receive a data signal composed of image data and generate and transmit a control signal such as a clock signal and so forth, an interface 200 configured to transmit the data signal and the control signal to a plurality of data drivers, the plurality of data drivers 300 configured to receive the data signal and the control signal from the interface 200, supply the received signals to a display panel to display an image and output LOCK signals indicative of the state information thereof, and a monitoring unit configured to feed back the state information of the data drivers 300 to the timing controller 100 so that the data drivers 300 can be monitored. The data drivers 300 inactivate and output the LOCK signal when they are in an abnormal state. The timing controller 100 receives the inactivated LOCK signal from the monitoring unit and can monitor the states of the data drivers 300.
The interface (I/F) 200 comprises a conventional interface which transmits the data signal and the control signal from the timing controller 100 to the data drivers 300. Examples of the interface 200 may include a multi-drop transmission type interface in which data drivers share a data signal line and a clock signal line, a PPDS (point-to-point differential signaling) transmission type interface in which data signals are separately supplied to respective data drivers and a clock signal is shared by the data drivers, and an interface in which data signals having a clock signal embedded therein are transmitted to data drivers through respective independent signal lines.
The interface 200 may comprise a novel interface which is disclosed in Korean Patent Application No. 10-2008-0102492 by the present applicant and in which data and clock signals are transmitted using a single level signal in which a clock signal is embedded between data signals at the same level so that a receiver can recover the data and clock signals during a clock training interval.
The monitoring unit can comprise various units which are connected between the data drivers 300 and the timing controller 100 and can feed back the state information of the data drivers 300. It is to be noted that the configuration of the monitoring unit is not limited to those of first through fifth embodiments of the present invention which will be described below with reference to
In this way, by continuously monitoring changes in the states of the data drivers 300 through the monitoring unit, if at least one of the data drivers 300 is in an abnormal state, the timing controller 100 transmits appropriate data signal and control signal so that the data driver 300 in the abnormal state can be quickly recovered to a normal state. The data driver 300 can neglect the signals inputted through the interface 200 until it is recovered to the normal state or can receive an appropriate signal which is helpful to the recovery of the data driver 300 to the normal state.
Of course, the monitoring unit is not limited to a specified type of interface and can be applied irrespective of the specification of an interface. Accordingly, while specified interfaces will be described below, it is to be appreciated that the interface 200 according to the present invention is not limited to such interfaces and can be configured in a variety of ways.
Referring to
The transmission data transmitted from the timing controller 100 is a signal in which the clock signal is embedded between the data signals at the same level. The interface 200 does not have a separate signal line for transmitting the clock signal, and transmits only a CED (clock embedded data) signal, in which the clock signal is embedded between the data signals at the same level, to the data drivers 300 using the single signal line. The CED signal can comprise not only a differential signal but also a single-ended signal.
Referring to
The data drivers 300 recover the received clock signal which is to be used for data sampling, depending upon the CED signal transmitted during the clock training interval after the LOCK signal received from the timing controller 100 or adjoining data drivers 300 is in an “H” state (a logic high state). If the received clock signal is stabilized, LOCK signals LOCK1 through LOCKN (N is a positive integer that indicates the number of the data drivers 300) are outputted as the “H” state. That is to say, after the data drivers 300 receive the LOCK signal LOCK0 of the “H” state informing that the clock signal is stabilized, from the timing controller 100, when the received clock signal is stabilized, the data drivers 300 sequentially output the LOCK signals LOCK1 through LOCKN-1 of the “H” state to next data drivers 300. Finally, the timing controller 100, which has received the LOCK signal LOCKN of the “H” state from the data driver 300, ends the clock training after the lapse of a predetermined time and starts the transmission of the data signals with the clock signal embedded therebetween.
While it is shown in
The monitoring unit includes a sequential transmission section 410 which sequentially connects the data drivers 300 with one another such that the data drivers 300 can transmit their respective state information to other adjoining data drivers 300, and which connects the finally positioned data driver 300 to the timing controller 100 such that the finally positioned data driver 300 can transmit and feed back the state information thereof to the timing controller 100.
Accordingly, if at least one data driver 300 is in an abnormal state due to electromagnetic interference (EMI) or noise while the data received from the timing controller 100 is transmitted to the display panel, the corresponding data driver 300 inactivates the LOCK signal and outputs the LOCK signal of an “L” state (a logic low state) to another adjoining data driver 300.
If the LOCK signal, which is transmitted from at least one data driver 300 to another adjoining data driver 300, is in the “L” state in this way, the LOCK signal which is outputted from the another data driver 300 also has the “L” state. Therefore, if the LOCK signal LOCK8 of the “L” state is inputted from the final data driver D-IC8 to the timing controller 100, the timing controller 100 immediately interrupts the transmission of the CED signal, and starts and implements the clock training until the LOCK signal LOCK8 which is fed back from the final data driver D-IC8 is again in the “H” state, thereby stabilizing the receivers of the data drivers 300.
If the LOCK signal is activated again to the “H” state in this way, the timing controller 100 ends the clock training after the lapse of the predetermined time and transmits again the CED signal as the transmission data to the data drivers 300.
Therefore, since the LOCK signal transmitted between adjoining data drivers 300 is finally fed back to the timing controller 100 in this way, the changes in the states of the data drivers 300 can be continuously monitored, and if an abnormality occurs in a certain data driver 300, the corresponding data driver 300 can be quickly recovered to the normal state.
Referring to
The timing controller 100 is configured not to embed a clock signal between data signals and transmit the data signal and the clock signal to respective data drivers 300 by way of a multi-drop transmission type interface or a PPDS (point-to-point differential signaling) transmission type interface. The interface 200 according to the present invention is not limited to such types of interfaces and can of course be configured to transmit transmission data in which a clock signal is embedded between data signals at a single level.
The monitoring unit includes a LOCK signal output section 420 which independently outputs LOCK signals indicative of the state information of the plurality of respective data drivers 300, and a logic gate 421 which combines the plurality of LOCK signals outputted from the plurality of data drivers 300, executes a logical operation and outputs a resultant signal. At this time, it is of course that the output terminal of the logic gate 421 must be connected to the timing controller 100 so as to transmit and thereby feed back a state information signal LOCK9 from the data drivers 300, which is obtained by combining the LOCK signals, to the timing controller 100.
As in the aforementioned embodiment, the LOCK signals LOCK1 through LOCK8 outputted from the data drivers 300 and transmitted to the LOCK signal output section 420 are in the logic high (H) state as an activated state when the data drivers 300 are in normal states, and are in the logic low (L) state as an inactivated state when at least one of the data drivers 300 is in an abnormal state.
It is preferred that the logic gate 421 comprise an OR gate which outputs a logic low state when even any one input is in a logic low state, so that, when even any one of the plurality of LOCK signals LOCK1 through LOCK8 outputted from the data drivers 300 is in an inactivated state, the corresponding state change can be transmitted to the timing controller 100.
In this way, if the LOCK signal from at least one data driver 300 is in the inactivated state, the receiver of the corresponding data driver 300 indicates the abnormal state, and the data driver 300 is configured to neglect the data signals continuously inputted thereto through the interface 200 and drive the display panel using previously inputted data.
The timing controller 100, which recognizes the abnormal state of the data driver 300 from the LOCK signal transmitted from the logic gate 421, transmits a preamble signal as deskewing data between the data signal and the clock signal or a clock training signal for the recovery of the clock signal, to the data driver 300 after the lapse of a preset time so as to wait until the LOCK signals of all the data drivers 300 represent the logic high (H) state indicating the activated state.
Referring to
Because the timing controller 100, the interface 200 and the data drivers 300 are the same as those of the first and second embodiments, only the configuration of the monitoring unit will be mainly described below.
The monitoring unit includes first through Nth sequential transmission sections which are configured to divide the plurality of data drivers 300 into N (N is a natural number identical to or greater than 1) number of groups each of which is composed of one or more data drivers 300, and connect the data drivers of the respective groups with one another in such a way as to sequentially transmit LOCK signals to adjoining data drivers 300, wherein the last data drivers of the respective groups which receive the LOCK signals are connected to the timing controller 100 such that the LOCK signals of the respective groups can be transmitted and fed back to the timing controller 100.
While it is illustrated in
Referring to
The data driver D-IC1, which is disposed last in the direction of the first sequential transmission section 431, is configured to transmit the state information thereof to the timing controller 100, and the data driver I-IC8, which is disposed last in the direction of the second sequential transmission section 432, is also configured to transmit the state information thereof to the timing controller 100.
Hence, as shown in
The respective data drivers 300 output the LOCK signals of an “H” state (a logic high state) to other adjoining data drivers 300 in normal states, and outputs the LOCK signals of an “L” state (a logic low state) to other adjoining data drivers 300 in abnormal states. When the LOCK signals received from the adjoining data drivers 300 are in the “L” state, the respective following data drivers 300 output the “L” state irrespective of their states.
Accordingly, if the LOCK signal LOCK1 changed to the “L” state is inputted from the last data driver D-IC1 of the first sequential transmission section 431 to the timing controller 100 or the LOCK signal LOCK8 changed to the “L” state is inputted from the last data driver D-IC8 of the second sequential transmission section 432 to the timing controller 100, the timing controller 100 immediately interrupts the transmission of a CED signal, and starts and implements a clock training until the fed-back LOCK signals LOCK1 and LOCK8 are recovered to the “H” state, thereby stabilizing the receivers of the data drivers 300. At this time, since the timing controller 100 can grasp the position of a data driver 300 which is in the abnormal state, from the fed-back signal, the corresponding data driver 300 can be quickly recovered to the normal state.
Referring to
Because the timing controller 100, the interface 200 and the data drivers 300 are the same as those of the first, second and third embodiments, only the configuration of the monitoring unit will be mainly described below.
The monitoring unit includes first through Mth LOCK signal output sections which are configured to divide the plurality of data drivers 300 into M (M is a natural number identical to or greater than 1) number of groups each of which is composed of one or more data drivers 300, and transmit independently the LOCK signals outputted from the data drivers constituting the respective groups to logic gates, and first through Mth logic gates which are configured to receive the LOCK signals transmitted from the respective groups of the first through Mth LOCK signal output sections, execute logical operations, and feed back output values thereof to the timing controller 100.
While it is illustrated in
Referring to
In the fourth embodiment, as shown in
The LOCK signals LOCK1 through LOCK4 outputted from respective data drivers 300 and transmitted to the first LOCK signal output section 441 and the LOCK signals LOCK5 through LOCK8 outputted from respective data drivers 300 and transmitted to the second LOCK signal output section 443 represent a logic high (H) state as an activated state when the data drivers 300 are in normal states and represent a logic low (L) state as an inactivated state when at least one of the data drivers 300 is in an abnormal state.
It is preferred that the first logic gate 442 comprise an OR gate which executes a logical operation such that, when even any one of the plurality of LOCK signals LOCK1 through LOCK4 outputted from the corresponding data drivers 300 represents the inactivated state, the first logic gate 442 can transmit the signal LOCK0 indicating the stage change to the timing controller 100, and that the second logic gate 444 comprise an OR gate which executes a logical operation such that, when even any one of the plurality of LOCK signals LOCK5 through LOCK8 outputted from the corresponding data drivers 300 represents the inactivated state, the second logic gate 444 can transmit the signal LOCK0 indicating the stage change to the timing controller 100.
When the LOCK signal of at least one data driver 300 represents the inactivated state, since the receiver of the corresponding data driver 300 is in the abnormal state, the data driver 300 is configured to neglect the data signals which are continuously inputted thereto through the interface 200 and drive the display panel using previously inputted data.
Due to the fact that logic gates for receiving the LOCK signals transmitted from the plurality of data drivers 300 as signals indicative of state information and then executing logical operations are provided in a plural number, the logical operations can be quickly executed, and since the timing controller can easily grasp the approximate position of the data driver 300 which has a problem, it is possible to deal with the abnormal state of the data driver 300.
Referring to
Because the timing controller 100, the interface 200 and the data drivers 300 are the same as those of the first through fourth embodiments, only the configuration of the monitoring unit will be mainly described below. Further, the interface 200 can be configured to transmit the data signal and the clock signal to the respective data drivers 300 according to a multi-drop transmission scheme or a point-to-point differential signaling transmission scheme or to transmit transmission data in which a clock signal is embedded between data signals at a single level, to the data drivers 300.
The monitoring unit includes independent feed-back sections 451 and 452 which are configured to independently output LOCK signals indicative of state information of the plurality of data drivers 300 and feed back the LOCK signals to the timing controller 100 through independent transmission lines connected between the respective data drivers 300 and the timing controller 100.
Similar to the first through fourth embodiments, LOCK signals LOCK1 through LOCK8 outputted from the plurality of data drivers 300 have a logic high (H) state indicating an activated state when the data drivers 300 are in normal states and a logic low (L) state indicating an inactivated state when at least one of the data drivers 300 is in an abnormal state.
Thus, if at least one of the LOCK signals transmitted through the independent feed back sections 451 and 452 is inactivated, the timing controller 100 can immediately recognize that the receiver of the corresponding data driver 300 is in an abnormal state. Then, the corresponding data driver 300 neglects the data signals continuously inputted thereto through the interface 200 and drives the display panel using previously inputted data. The timing controller 100, which has recognized the abnormal state of the data driver 300 through the independent feed back sections 451 and 452, transmits a preamble signal as deskewing data.
As described above, in the present invention, differently from the conventional art in which data drivers simply receive data signals, etc. from a timing controller, respective data drivers sequentially transmit LOCK signals indicating the states thereof to adjoining data drivers and then finally to a timing controller, LOCK signals outputted from respective data drivers are combined by at least one logic gate and then transmitted to a timing controller, or LOCK signals of respective data drivers are transmitted to a timing controller through independent feed back sections. As a consequence, the timing controller can recognize a change in the states of the data drivers and can quickly take necessary measures such as by transmitting appropriate data or control signal.
As is apparent from the above description, the display driving system with a unit for monitoring data drivers according to the present invention renders advantages in that the monitoring unit is provided to feed back a LOCK signal indicative of a change in the state of a data driver to a timing controller so that the state of the data driver can be monitored, and the timing controller having recognized the state of the data driver can transmit a data signal and a control signal appropriate for normalizing the data driver operating in an abnormal state so that the data driver can be quickly recovered to a normal operation.
Although preferred embodiments of the present invention have been described for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and the spirit of the invention as disclosed in the accompanying claims.
Jeon, Hyun-Kyu, Moon, Yong-Hwan
Patent | Priority | Assignee | Title |
10410599, | Aug 13 2015 | Samsung Electronics Co., Ltd. | Source driver integrated circuit for ompensating for display fan-out and display system including the same |
10453406, | Dec 29 2016 | LG Display Co., Ltd.; LG DISPLAY CO , LTD | Display device, driving controller, and driving method |
11315478, | Dec 26 2019 | LG Display Co., Ltd. | Display device |
9984655, | Mar 06 2015 | Silicon Works Co., Ltd. | Apparatus and method for transmitting display signal having a protocol including a dummy signal and a clock signal |
Patent | Priority | Assignee | Title |
6995519, | Nov 25 2003 | Global Oled Technology LLC | OLED display with aging compensation |
7212186, | Jan 27 2003 | Sony Corporation | Image display device and image display panel |
7724225, | Mar 08 2005 | AU Optronics Corp | Display panel for liquid crystal display |
7847779, | Mar 29 2006 | Novatek Microelectronics Corp. | Method and apparatus of transmitting data signals and control signals via an LVDS interface |
8134550, | Aug 30 2006 | SAMSUNG DISPLAY CO , LTD | Display device, driving method thereof and display driver therefor |
20030160753, | |||
20040061675, | |||
20040227716, | |||
20050007359, | |||
20060202936, | |||
20090153541, | |||
20100033453, | |||
20100141636, | |||
20100149083, | |||
20100156879, | |||
20100156885, | |||
20100225637, | |||
20110043493, | |||
CN101286287, | |||
CN1536544, | |||
JP11338412, | |||
JP200066654, | |||
JP2006184654, | |||
JP2007511011, | |||
JP2010107933, | |||
JP6063139, | |||
JP6130919, | |||
JP663139, | |||
KR100883778, | |||
KR1020080102492, | |||
WO2005050448, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Feb 17 2010 | JEON, HYUN KYU | SILICON WORKS CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 024008 | /0361 | |
Feb 17 2010 | MOON, YONG HWAN | SILICON WORKS CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 024008 | /0361 | |
Mar 01 2010 | Silicon Works Co., Ltd. | (assignment on the face of the patent) | / |
Date | Maintenance Fee Events |
Oct 07 2016 | STOL: Pat Hldr no Longer Claims Small Ent Stat |
Jan 12 2017 | M1551: Payment of Maintenance Fee, 4th Year, Large Entity. |
Jan 06 2021 | M1552: Payment of Maintenance Fee, 8th Year, Large Entity. |
Date | Maintenance Schedule |
Jul 23 2016 | 4 years fee payment window open |
Jan 23 2017 | 6 months grace period start (w surcharge) |
Jul 23 2017 | patent expiry (for year 4) |
Jul 23 2019 | 2 years to revive unintentionally abandoned end. (for year 4) |
Jul 23 2020 | 8 years fee payment window open |
Jan 23 2021 | 6 months grace period start (w surcharge) |
Jul 23 2021 | patent expiry (for year 8) |
Jul 23 2023 | 2 years to revive unintentionally abandoned end. (for year 8) |
Jul 23 2024 | 12 years fee payment window open |
Jan 23 2025 | 6 months grace period start (w surcharge) |
Jul 23 2025 | patent expiry (for year 12) |
Jul 23 2027 | 2 years to revive unintentionally abandoned end. (for year 12) |